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Letter
LpxC Inhibitors: Design, Synthesis, and Biological Evaluation of Oxazolidinones as Gram-negative Antibacterial Agents Haruaki Kurasaki, Kosuke Tsuda, Mariko Shinoyama, Noriko Takaya, Yuko Yamaguchi, Ryuta Kishii, Kazuhiko Iwase, Naoki Ando, Masahiro Nomura, and Yasushi Kohno ACS Med. Chem. Lett., Just Accepted Manuscript • DOI: 10.1021/acsmedchemlett.6b00057 • Publication Date (Web): 05 Apr 2016 Downloaded from http://pubs.acs.org on April 7, 2016
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ACS Medicinal Chemistry Letters
LpxC Inhibitors: Design, Synthesis, and Biological Evaluation of Oxazolidinones as Gram-negative Antibacterial Agents Haruaki Kurasaki*, Kosuke Tsuda, Mariko Shinoyama, Noriko Takaya, Yuko Yamaguchi, Ryuta Kishii, Kazuhiko Iwase, Naoki Ando, Masahiro Nomura, and Yasushi Kohno Watarase Research Center, Kyorin Pharmaceutical Co., Ltd., 1848 Nogi, Nogi-machi, Shimotsuga-gun, Tochigi 329-0114, Japan
ABSTRACT: Herein we report a scaffold-hopping approach to identify a new scaffold with a zinc binding head group. Structural information was used to give novel oxazolidinone-based LpxC inhibitors. In particular, the most potent compound, 23j, showed a low efflux ratio, nanomolar potencies against E. coli LpxC enzyme, and excellent antibacterial activity against E. coli and K. pneumoniae. Computational docking was used to predict the interaction between 23j and E. coli LpxC, suggesting that the interactions with C207 and C63 contribute to the strong activity. These results provide new insights into the design of next-generation LpxC inhibitors.
KEYWORDS: Antibacterial, Gram-negative bacteria, LpxC, scaffold hopping, oxazolidinone
In recent years, infections caused by antibiotic-resistant bacteria have emerged as major threats to human communities worldwide.1 However, the late-stage clinical development pipeline for antibacterials has been unacceptably lean in recent decades.2 In particular, no drugs have reached advanced stages of development for the treatment of infection due to multidrug-resistant Gram-negative bacteria. Thus, there is a great need to develop new mechanisms by which Gram-negative antibacterial agents can combat bacterial antibiotic resistance.3,4
Among the well-characterized compounds, threonylhydroxamate derivatives are representative LpxC inhibitors, such as 2 (CHIR-090) and 3 (LPC-009) (Figure 1 (a)).18,19 According to a few reports on the binding modes of these compounds, the threonyl-hydroxamate group of 2 and that of 3 occupy the active site, and its diphenyl acetylene or phenyldiyne group penetrates the hydrophobic passage.19-21
a
One of the emerging targets in Gram-negative bacteria is LpxC, an essential enzyme in the lipid A biosynthetic pathway. Because LpxC does not show homology to any mammalian protein, it is a promising antibiotic target for developing novel therapeutics against multidrug-resistant Gram-negative pathogens.5 LpxC inhibitors have drawn much attention in new entities for Gram-negative antibacterial agents.6 To date, extensive investigations have been carried out on the mechanism underlying the LpxC enzyme.7,8 Those studies have identified a zinc ion to catalyze deacetylation and a hydrophobic tunnel binding a myristate fatty acyl chain of the natural substrate. Merck researchers discovered 1 (L-161,240) containing an oxazoline scaffold in the mid-1990s,6 and recently several LpxC inhibitors have been reported as antibacterial agents,9-17 although to our knowledge, none have reached the market yet.
O
N
N H
O
O
OH H N
O
HN OH
O
O OH
N H
O
OH H N
OH
O
O N
1 (L-161,240)
b
C63
C63 H
O N H
*
3 (LPC-009)
2 (CHIR-090)
Scaffold Hopping
H N
O
OH O OH
Me
Zn
T191 K239 Binding schematic for threonine-based inhibitors bound to E. coli LpxC
cycloalkyl or cycloaryl H N
N
OH
O
*
sp2 or sp 3
Zn T191 Conformationally-locked cyclic compounds
Figure 1. (a) Threonine-based LpxC inhibitors. (b) Scaffold hopping approach to LpxC inhibitors.
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Scheme 1. Synthesis of Initially Designed Compoundsa
a
Reagents and conditions: (a) 5-Methoxycarbonyl-2-pyrone, pyridine, 100 oC, 37%; (b) K2CO3, MeOH, rt, 86-96%; (c) 4-(4Iodobenzyl)morpholine, PdCl2(PPh3)2, CuI, Et3N, THF, rt, 30-62%; (d) LiOH aq., THF/MeOH, rt; (e) THPONH2, EDCI or HATU, iPr2NEt, DMF, rt; (f) 4 M HCl, dioxane/MeOH, rt, or TFA, CH2Cl2, rt, 46-61%; (g) Methyl (2S)-glycidate or methyl (2R)-glycidate, TfOLi, CH3CN, 60 oC, 34%; (h) Bromoacetylbromide, Et3N, THF, rt; (i) NaH, THF, rt, 22% (2 steps); (j) CDI, CH3CN, 60 oC, 46% (2 steps from 4); (k) (R)-3-Oxo-(tritylamino)-propionic acid methyl ester, NaBH(OAc)3, CH2Cl2, rt, 24%; (l) Triphosgene, Et3N, CH2Cl2, rt, 82%; (m) HCOOH aq., THF 65 oC, 61%; (n) NH2OH aq., iPrOH, rt, 80%.
Herein we report a scaffold hopping approach to identify a new scaffold with a zinc-binding head group. Additionally, we describe the synthesis, biological evaluation, and docking analysis of oxazolidinone-based LpxC inhibitors. Among these compounds, 23j showed remarkable antibacterial activity.
lylated under basic conditions, followed by Sonogashira coupling with 4-(4-iodobenzyl)morpholine. Finally, methyl ester 6 was converted to the corresponding hydroxamic acid 7 in three steps: employing LiOH hydrolysis, coupling with O-THPhydroxylamine, and acidic hydrolysis. A morpholin-3-one 9 or
In order to discover a novel scaffold to replace the threonine moiety, we embarked on a scaffold hopping approach utilizing structural information. The crystal structure and detailed analysis of the binding site for E. coli LpxC complexed with the threonine-based inhibitor LPC-009 have been reported.19,20 Inspection of the available co-crystal structures20 indicated that the threonyl hydroxy group and benzamide moiety make key contacts with C63, T191, and K239 (left part in Figure 1 (b)). It is striking that the C=O bond of the benzamide and the C-H bond of threonyl α-methine lie in the same plane. We hypothesized that adjustment of the conformation of the amide and the hydroxamic acid makes better interactions with C63, T191, and zinc, thus makes it possible to improve activity even though the interaction with K239 is not available.23 Therefore, we decided to incorporate the conformationally restricted cyclic moiety to retain the hydrogen-bonding network and overlapping with the positions of the central phenyl moiety and hydroxamic acid group of threonine-based inhibitors, as shown at right in Figure 1 (b).
Table 1. IC50 and MIC Values of Initial Compounds
A diphenyl acetylene hydrophobe, similar to 2 (CHIR-090), was chosen as a starting point for the initially designed compounds. The syntheses of these compounds are described in Scheme 1. All designed compounds were derived from 4[(trimethylsilyl)ethynyl]aniline (4). Pyridone 5 was prepared by heating 4 with the corresponding pyrone in pyridine. For the preparation of the diphenyl acetylene unit, 5 was desi-
E.c. IC50 (nM)
E.c.a
E.c.b
K.p.c
2
3
0.13
0.01
0.25
7
1000
8
1
64
(S)-13
510
2
0.25
16
(S)-14
130
0.5
0.06
2
(R)-14
260
1
0.13
8
700
8
0.5
>32
Structure R=
cpd
MIC (µg/mL)
O NH
(S)-18
H N
N
*
OH
O
a Wild-type E. coli TG1 strain. bEfflux mutant (acrB-) E. coli KAM3 strain. cWild-type K. pneumoniae ATCC 13883 strain.
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Scheme 2. Synthesis of Oxazolidinone-Based Diyne Compoundsa
I
R
NH2
a,b
NH2 1
R
NH2
c
d,e R1
1
R2
R2
R2 19f (R1 = OMe, R2 = H) 19g (R1 = F, R2 = H) 19h (R1 = H, R2 = NO2) 19j (R1 = H, R2 = F)
R3
20a (R1 = H, R2 = H) 20f (R1 = OMe, R2 = H) 20g (R1 = F, R2 = H) 20h (R1 = H, R2 = NO2) 20j (R1 = H, R2 = F)
O
21a (R1 = H, R2 = H, R3 = hydroxyethyl) 21b (R1 = H, R2 = H, R3 = hydroxypropyl) 21c (R1 =H, R2 = H, R3 = O-THP-hydroxymethyl c-propyl) 21e (R1 = H, R2 = H, R3 = c-propyl) 21f (R1 = OMe, R2 = H, R3 = c-propyl) 21g (R1 = F, R2 = H, R3 = c-propyl) 21 (R1 = H, R2 = NO2, R3 = c-propyl) 21j (R1 = H, R2 = F, R3 = c-propyl)
O N
O COOMe
h
R1
R
R2
R3 2
HN OH O
R1 2
1
O N
R3
3
22a (R = H, R = H, R = hydroxyethyl) 22b (R1 = H, R2 = H, R3 = hydroxypropyl) 22c (R1 = H, R2 = H, R3 = O-THP-hydroxymethyl c-propyl) 22d (R1 = H, R2 = H, R3 = hydroxymethyl c-propyl) 22e (R1 = H, R2 = H, R3 = c-propyl) 22f (R1 = OMe, R2 = H, R3 = c-propyl) 22g (R1 = F, R2 = H, R3 = c-propyl) 22h (R1 = H, R2 = NO2, R3 = c-propyl) g 22i (R1 = H, R2 = NH2, R3 = c-propyl) 22j (R1 = H, R2 = F, R3 = c-propyl)
f
23a (R1 = H, R2 = H, R3 = hydroxyethyl) 23b (R1 = H, R2 = H, R3 = hydroxypropyl) 23d (R1 = H, R2 = H, R3 = hydroxymethyl c-propyl) 23e (R1 = H, R2 = H, R3 = c-propyl) 23f (R1 = OMe, R2 = H, R3 = c-propyl) 23g (R1 = F, R2 = H, R3 = c-propyl) 23h (R1 = H, R2 = NO2, R3 = c-propyl) 23i (R1 = H, R2 = NH2, R3 = c-propyl) 23j (R1 = H, R2 = F, R3 = c-propyl)
a
Reagents and conditions: (a) TMS-acetylene, PdCl2(PPh3)2, CuI, Et3N, THF, rt; (b) K2CO3, MeOH, rt, 81-100% (2 steps); (c) Acetylene, NiCl2 6H2O, TMEDA, THF, rt, 24-73%; (d) Methyl (2S)-glycidate, TfOLi, CH3CN, 60 oC; (e) i. CDI, CH3CN, 60 oC, 16-56% (2 steps); ii. NaH, THF, 0 oC, 27% (3 steps) for only 22g; (f) PPTS, MeOH, 50 oC, 77%; (g) Zn, AcOH, rt, 88%; (h) NH2OH aq., iPrOH/THF, rt, 3786%.
oxazolidinone 10 was formed by Lewis acid−induced epoxide ring opening using chiral methyl glycidate with 4, followed by cyclization with bromoacetyl bromide or CDI. Meanwhile, for imidazolidinone, reductive alkylation of the corresponding aldehyde and 4, followed the by the addition of triphosgene, affords 16. Target compounds 13, 14, and 18 were afforded from 9, 10, and 16 in a similar manner as hydroxamic acid 7. Some of the newly designed compounds exhibited good cellular activity against E. coli and K. pneumoniae, although their activities in cell-free enzymatic assay were lower than that of 2 (Table 1). Pyridone 7 showed weak enzyme inhibitory activity and exhibited antibacterial activities with a minimum inhibitory concentration (MIC) of 8 µg/mL against an E. coli wild-type strain. Replacement of the pyridone moiety with the morpholine-3-one moiety improved IC50 value slightly and increased antibacterial activity 4-fold (compound 7 versus (S)13). To our delight, ring compression to the oxazolidinone (S)14 resulted in much higher activity. Similar shifts in IC50 value in E. coli relative to the MIC values of E. coli and K. pneumoniae were observed (compound (S)-13 versus (S)-14). Interestingly, (S)-14 showed a good E. coli MIC value, although its enzyme activity was significantly lower than compared to that of 2. At the same time, the absolute configuration in the 5position of oxazolidinone was inverted from S to R. The activity of (R)-14 was slightly lower than that of its Senantiomer (2-fold shift in IC50 and MIC values). The substitution of oxazolidinone with imidazolidinone (S)-18 led to the weakening of activity.
With oxazolidinone (S)-14 in hand, we next varied the diphenyl acetylene moiety in order to evaluate the structureactivity relationship (SAR) of the hydrophobic group further. According to the reported co-crystal structures (3NZK24 and 3P3G20), the terminal morpholine group of 2 and the phenyl group of 3 are surrounded by solvent-exposed lipophilic amino acid residues (M195, I198, Q202, S211, and F212) at the entrance to the hydrophobic passage. In particular, the terminal phenyl group of 3 forms an edge-to-face π−π interaction with F212.19 These findings suggest that an sp2-characterbearing moiety is suitable for interacting efficiently with F212.18-21 Thus, we explored diyne compounds having various terminal functional groups. Moreover, we examined the SAR of the substitution effect on the central phenyl ring because we expected new interactions between the substituent and the amino acids positioned at the exit to the hydrophobic passage.15 The synthesis of oxazolidinone-based inhibitors with modified hydrophobes can be found in Scheme 2. The preparation of target compounds was initiated by Sonogashira reactions of 4-iodoaniline derivatives with TMS-acetylene followed by deprotection of the TMS group. A diacetylene unit was synthesized via Ni-catalyzed coupling reactions of terminal alkynes.25 The desired hydroxamic acids were prepared in a manner similar to that described above. The results of the oxazolidinone-based hydrophobe screening can be found in Table 2. Hydroxyethyldiyne 23a retained
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its activity, and the extension of the alkyl chain such as in 23b showed a 3-fold increase in enzyme inhibitory activity and antibacterial activity. These results indicate that the terminal hydroxyl group was presumably located away from the hydrophobic passage. Potency increased slightly when the propyl group of 23b was replaced by the methyl cyclopropyl group having an sp2 character, such as in 23d, which likely increased the hydrophobic interaction. Moreover, the removal of the hydroxymethyl group from 23d increased K. pneumoniae antibacterial activity 4-fold, although the enzyme inhibitory activity was unchanged (23e). Table 2. IC50 and MIC Values of Oxazolidinones O O R
H N
N S
OH
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Figure S2, Supporting Information). On the basis of these results, we next investigated substituent modification at the meta-position of the N-phenyl moiety, which we did not expect to appreciably affect the dihedral restrictions. The introduction of an electron-donating amino group to give 23h significantly weakened enzyme inhibitory activity, whereas the strongly electron-withdrawing nitro group 23i retained potency. Encouraged by this result, we introduced another electronwithdrawing and small lipophilic substituent. Changing NO2 to F enhanced activity remarkably (E. coli MIC = 0.016 µg/mL and K. pneumoniae MIC = 0.063 µg/mL). As a result of this tuning of the hydrophobic group, 23j was over 30-fold more potent than (S)-14. On the other hand, these new oxazolidiones had little or no effect against Pseudomonas aeruginosa and Acinetobacter baumannii (see Table S1, Supporting Information).
O
E.c. IC50 (nM)
E.c.a
E.c.b
K.p.c
2
3
0.13
0.01
0.25
(S)-14
130
0.5
0.063
2
23a
140
0.5
0.125
8
23b
58
0.125
0.031
2
23dd
20
0.125
0.016
1
23e
18
0.063
0.016
0.25
23f
2000
4
0.5
32
23g
200
0.5
0.25
4
23h
270
0.25
0.063
2
23i
27
0.125
0.031
1
23j
6
0.016
0.004
0.063
cpd
Structure R=
MIC (µg/mL)
a Wild-type E. coli TG1 strain. bEfflux mutant (acrB-) E. coli KAM3 strain. cWild-type K. pneumoniae ATCC 13883 strain. d Mixture of diastereomers.
Next we examined the SAR of the substitution effect on the central phenyl ring of 23e. The introduction of a methoxy group at the ortho- position of the N-phenyl moiety resulted in a dramatic decrease in enzyme inhibitory activity, suggesting that dihedral restriction between phenyl and oxazolidinone due to the resonance and the steric effect of the methoxy group may be critical for the activity (compound 23e versus 23f). The fluorine-substituted 23g was more active than 23f, possibly because 23g may have fewer dihedral restrictions (see
Figure 2. Comparative analysis of threonine-based and oxazolidinone-based inhibitors. (a) Threonine-based inhibitor 3 (LPC009) bound co-crystal structure in E. coli LpxC (3P3G) showing key hydrogen bonds (pink dotted lines) and interaction with zinc (gray dotted lines).20 (b)(c) Docking pose of 23j bound to E. coli LpxC showing partially resected solvent-accessible surface (gray).
To examine the binding mode, we performed a docking study of 23j to E. coli LpxC (Figure 2). The model clearly shows that the hydroxamic acid chelates the catalytic zinc ion with its two oxygen atoms. Additionally, it forms a hydrogen bond with T191 and E78, as in the case of 3 (LPC-009). On the other hand, the threonyl hydroxyl group of 3 forms a hydrogen bond with K239, but this interaction is not observed in the case of 23j. As expected, the carbonyl oxygen atom of oxazolidinone is capable of accepting a hydrogen bond from the backbone NH of C63, corresponding to the oxygen atom in the benzamide moiety of 3. Interestingly, the model indicates that the oxygen atom in position 1 of the oxazolidinone ring makes dual contacts with the backbone NH and the side chain thiol of C63. Also, it suggests that the fluorine atom on the phenyl group interacts with the thiol group of C207 (Figure 2 (b)(c)).26 The fluorine atom contributes to the strong inhibition of enzymatic activity and antibacterial activity (compound 23e versus 23j). It appears that such additional interactions with C207 and C63, as in the case of 23j, plays an important role in the remarkable activity enhancement without the key hydrogen-bonding interaction with K239, such as occurs in 3. In general, oxazolidinone-based compounds can result in 2- to 8fold lower efflux ratios (MIC value of wild-type strain/MIC
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value of efflux knockout strain). The strong activity of 23j against the E. coli wild-type strain contributes to the lower efflux ratio. In summary, we conducted a scaffold hopping approach, which restricts the conformation of the threonine moiety, to discover a new series of LpxC inhibitors. We found oxazolidinone-based inhibitors. The most potent compound, 23j, exhibited nanomolar potencies against E. coli LpxC enzyme, excellent antibacterial activity against E. coli and K. pneumoniae, and a low efflux ratio. Docking analysis of 23j with E. coli LpxC suggested that the oxygen atom in position 1 of the oxazolidinone ring makes dual contacts with the backbone NH and the side chain thiol of C63 and the fluorine atom on the phenyl group interacts with the thiol group of C207. The interactions with C207 and C63 may contribute to the strong activity of 23j. This observation provides new insights into the rational design of new LpxC inhibitors. These oxazolidinonebased inhibitors represent promising leads for further exploration as antibacterial agents.
ASSOCIATED CONTENT
(4) Silver, L. L. Challenges of antibacterial discovery. Clin. Microbiol. Rev. 2011, 24, 71-109. (5) Young, K.; Silver, L. L.; Bramhill, D.; Cameron, P.; Eveland, S. S.; Raetz, C. R.; Hyland, S. A.; Anderson, M. S. The envA permeability/cell division gene of Escherichia coli encodes the second enzyme of lipid A biosynthesis. UDP-3-O-(R-3-hydroxymyristoyl)-Nacetylglucosamine deacetylase. J. Biol. Chem. 1995, 270, 3038430391. (6) Onishi, H. R.; Pelak, B. A.; Gerckens, L. S.; Silver, L. L.; Kahan, F. M.; Chen, M. H.; Patchett, A. A.; Galloway, S. M.; Hyland, S. A.; Anderson, M. S.; Raetz, C. R. Antibacterial agents that inhibit lipid A biosynthesis. Science, 1996, 274, 980-982. (7) Coggins, B. E.; Li, X.; McClerren, A. L.; Hindsgaul, O.; Raetz, C. R.; Zhou, P. Structure of the LpxC deacetylase with a bound substrate-analog inhibitor. Nature Structural Biology 2003, 10, 645-651. (8) Clayton, G. M.; Klein, D. J.; Rickert, K. W.; Patel, S. B.; Kornienko, M.; Zugay-Murphy, J.; Reid, J. C.; Tummala, S.; Sharma, S.; Singh, S. B.; Miesel, L.; Lumb, K. J.; Soisson, S. M. Structure of the bacterial deacetylase LpxC bound to the nucleotide reaction product reveals mechanisms of oxyanion stabilization and proton transfer. J. Biol. Chem. 2013, 288, 34073-34080.
Supporting Information Synthetic method, characterization of compounds, protocols of biological evaluations, and computational methods. This material is available free of charge via the Internet at http://pubs.acs.org.
(9) Mansoor, U. F.; Vitharana, D.; Reddy, P. A.; Daubaras, D. L.; McNicholas, P.; Orth, P.; Black, T.; Siddiqui, M. A. Design and synthesis of potent Gram-negative specific LpxC inhibitors. Bioorg. Med. Chem. Lett. 2011, 21, 1155-1161.
AUTHOR INFORMATION Corresponding Author *(H.K.) Tel: +81280571551; Fax: +81280572336; E-mail:
[email protected].
Author Contributions All authors have approved of the final version of the manuscript.
Notes The authors declare no competing financial interest.
ACKNOWLEDGMENT We are thankful to H. Furuta of Kyorin Pharmaceutical Co., Ltd., for his mass spectrometry and infrared spectra expertise.
ABBREVIATIONS LpxC, UDP-3-O-[(R)-3-hydroxymyristoyl]-N-acetylglucosamine deacetylase; E.c., Escherichia coli; K.p., Klebsiella pneumoniae; MIC, minimum inhibitory concentration; CDI, 1,1’-carbonyl diimidazole; TMS, trimethylsilyl; THP, tetrahydropyranyl; Tr, trityl; TMEDA, tetramethylethylenediamine; c-propyl, cyclopropyl; HATU, 1-[Bis(dimethylamino)methylene]-1H-1,2,3triazolo[4,5-b]pyridinium 3-oxide hexafluorophosphate; EDCI, 1Ethyl-3-(3-dimethylaminopropyl)carbodiimide; PPTS, pyridinium p-toluenesulfonate.
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(15) Hale, M. R.; Hill, P.; Lahiri, S.; Miller, M. D.; Ross, P.; Alm, R.; Gao, N.; Kutschke, A.; Johnstone, M.; Prince, B.; Thresher, J.; Yang, W. Exploring the UDP pocket of LpxC through amino acid analogs. Bioorg. Med. Chem. Lett. 2013, 23, 2362-2367. (16) Murphy-Benenato, K. E.; Olivier, N.; Choy, A.; Ross, P. L.; Miller, M. D.; Thresher, J.; Gao, N. Hale, M. R. Synthesis, structure, and SAR of Tetrahydropyran-based LpxC inhibitors. ACS Med. Chem. Lett. 2014, 5, 1213-1218. (17) Szermerski, M.; Melesina, J.; Wichapong, K.; Löppenberg, M.; Jose, J.; Sippl, W.; Holl, R. Synthesis, biological evaluation and molecular docking studies of benzyloxyacetohydroxamic acids as LpxC inhibitors. Bioorg. Med. Chem. 2014, 22, 1016-1028. (18) Barb, A. W.; Jiang, L.; Raetz, C. R. H.; Zhou, P. Structure of the deacetylase LpxC bound to the antibiotic CHIR-090: Time-dependent inhibition and specificity in ligand binding. Proc. Natl. Acad. Sci. 2007, 104, 18433-18438. (19) Liang, X.; Lee, C.-J.; Chen, X.; Chung, H. S.; Zeng, D.; Raetz, C. R. H.; Li, Y.; Zhou, P.; Toone, E. J. Syntheses, structures and antibiotic activities of LpxC inhibitors based on the diacetylene scaffold. Bioorg. Med. Chem. 2011, 19, 852-860. (20) Lee, C.-J.; Liang, X.; Chen, X.; Zeng, D.; Joo, S. H.; Chung, H. S. Barb, A. W.; Swanson, S. M.; Nicholas, R. A.; Li, Y.; Toone, E. J.; Raetz, C. R. H.; Zhou, P. Species-specific and inhibitor-dependent conformations of LpxC: implications for antibiotic design. Chemistry & Biology 2011, 18, 38-47. (21) Liang, X.; Lee, C.-J.; Zhao, J.; Toone, E. J.; Zhou, P. Synthesis, structure, and antibiotic activity of aryl-substituted LpxC inhibitors. J. Med. Chem. 2013, 56, 6954-6966. (22) Lee, C. J.; Liang, X.; Gopalaswamy, R.; Najeeb, J.; Ark, E. D.; Toone, E. J.; Zhou, P. Structural basis of the promiscuous inhibitor susceptibility of Escherichia coli LpxC. ACS Chem. Biol. 2014, 9, 237-246. (23) Sun, H.; Tawa, G.; Wallqvist, A. Classification of scaffoldhopping approaches. Drug Discov. Today. 2012, 17, 310-324. (24) Cole, K. E.; Gattis, S. G.; Angell, H. D.; Fierke, C. A.; Christian, D. W. Structure of the metal-dependent deacetylase LpxC from Yersinia enterocolitica complexed with the potent inhibitor CHIR-090. Biochemistry 2011, 50, 258-265. (25) Yin, W.; He, C.; Chen, M.; Zhang, H.; Lei, A. Nickel-catalyzed oxidative coupling reactions of two different terminal alkynes using O2 as the oxidant at room temperature: facile syntheses of unsymmetric 1,3-diynes. Org. Lett. 2009, 11, 709–712. (26) According to the docking pose, the F・・・HS distance is 1.63 Å and the F・・・SH distance is 2.60 Å. No further information is available on the type of interaction. Generally, fluorine is a considerably weaker hydrogen-bond acceptor than oxygen or nitrogen due to the very low polarizability of fluorine atoms and their tightly contracted lone pairs.27 On the other hand, the latest PDB data suggest that fluorine is capable of forming halogen bonds with nitrogen and oxygen as well as sulfur.28 (27) Dunitz, J. D.; Taylor, R. Organic fluorine hardly ever accepts hydrogen bonds. Chem. Eur. J. 1997, 3, 89-98. (28) Sirimulla, S.; Bailey, J. B.; Vegesna, R.; Narayan, M. Halogen interactions in protein-ligand complexes: Implications of halogen bonding for rational drug design. J. Chem. Inf. Model. 2013, 53, 2781-2791.
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23j E.c. IC50: 6 nM E.c. MIC: 0.016 mg/mL K.p. MIC: 0.063 mg/mL
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